Interlaboratory Comparison of Branched GDGT Temperature and pH Proxies Using Soils and Lipid Extracts

Cindy De Jonge; Francien Peterse; Klaas G.J. Nierop; Thomas M. Blattmann; Marcelo Alexandre; Salome Ansanay-Alex; Thomas Austin; Mathieu Babin; Edouard Bard; Thorsten Bauersachs; Jerome Blewett; Brenna Boehman; Isla S. Castañeda; Junhui Chen; Martina L.G. Conti; Sergio Contreras; Julia Cordes; Nina Davtian; Bart van Dongen; Bella Duncan; Felix J. Elling; Valier Galy; Shaopeng Gao; Jens Hefter; Kai Uwe Hinrichs; Mitchell R. Helling; Mariska Hoorweg; Ellen Hopmans; Juzhi Hou; Yongsong Huang; Arnaud Huguet; Guodong Jia; Cornelia Karger; Brendan J. Keely; Stephanie Kusch; Hui Li; Jie Liang; Julius S. Lipp; Weiguo Liu; Hongxuan Lu; Kai Mangelsdorf; Hayley Manners; Alfredo Martinez Garcia; Guillemette Menot; Gesine Mollenhauer; B. David A. Naafs; Sebastian Naeher; Lauren K. O'Connor; Ethan M. Pearce; Ann Pearson; Zhiguo Rao; Marta Rodrigo-Gámiz; Chris Rosendahl; Frauke Rostek; Rui Bao; Prasanta Sanyal; Florence Schubotz; Wesley Scott; Rahul Sen; Appy Sluijs; Rienk Smittenberg; Ioana Stefanescu; Jia Sun; Paul Sutton; Jess Tierney; Eduardo Tejos; Joan Villanueva; Huanye Wang; Josef Werne; Masanobu Yamamoto; Huan Yang; Aifeng Zhou

doi:10.1029/2024GC011583

Interlaboratory Comparison of Branched GDGT Temperature and pH Proxies Using Soils and Lipid Extracts

Cindy De Jonge^*
, Francien Peterse
, Klaas G.J. Nierop
, Thomas M. Blattmann
, Marcelo Alexandre
, Salome Ansanay-Alex
, Thomas Austin
, Mathieu Babin
, Edouard Bard
, Thorsten Bauersachs
, Jerome Blewett
, Brenna Boehman
, Isla S. Castañeda
, Junhui Chen
, Martina L.G. Conti
, Sergio Contreras
, Julia Cordes
, Nina Davtian
, Bart van Dongen
, Bella Duncan

Felix J. Elling, Valier Galy, Shaopeng Gao, Jens Hefter, Kai Uwe Hinrichs, Mitchell R. Helling, Mariska Hoorweg, Ellen Hopmans, Juzhi Hou, Yongsong Huang, Arnaud Huguet, Guodong Jia, Cornelia Karger, Brendan J. Keely, Stephanie Kusch, Hui Li, Jie Liang, Julius S. Lipp, Weiguo Liu, Hongxuan Lu, Kai Mangelsdorf, Hayley Manners, Alfredo Martinez Garcia, Guillemette Menot, Gesine Mollenhauer, B. David A. Naafs, Sebastian Naeher, Lauren K. O'Connor, Ethan M. Pearce, Ann Pearson, Zhiguo Rao, Marta Rodrigo-Gámiz, Chris Rosendahl, Frauke Rostek, Rui Bao, Prasanta Sanyal, Florence Schubotz, Wesley Scott, Rahul Sen, Appy Sluijs, Rienk Smittenberg, Ioana Stefanescu, Jia Sun, Paul Sutton, Jess Tierney, Eduardo Tejos, Joan Villanueva, Huanye Wang, Josef Werne, Masanobu Yamamoto, Huan Yang, Aifeng Zhou

^*Corresponding author for this work

Swiss Federal Institute of Technology Zurich
Brown University
Université Claude Bernard Lyon 1
GNS Science
Université du Québec à Rimouski
Collège de France
Kiel University
RWTH Aachen University
Harvard University
Woods Hole Oceanographic Institution
University of Massachusetts
State Oceanic Administration China
University of York
Universidad Católica de la Santísima Concepción
University of Bremen
Autonomous University of Barcelona
University of Manchester
Victoria University of Wellington
Chinese Academy of Sciences
Alfred Wegener Institute - Helmholtz Centre for Polar and Marine Research
University of Wyoming
Royal Netherlands Institute for Sea Research - NIOZ
Sorbonne Université
Tongji University
Helmholtz Centre Potsdam - German Research Centre for Geosciences
Institute of Earth Environment
University of Plymouth
Max Planck Institute for Chemistry
University of Bristol
Hunan Normal University
University of Granada
Ocean University of China
Indian Institute of Science Education and Research, Kolkata
University of Pittsburgh
Stockholm University
Swiss Federal Institute for Forest, Snow and Landscape Research
University of Arizona
Hokkaido University
China University of Geosciences, Wuhan
Lanzhou University

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

Ratios of glycerol dialkyl glycerol tetraethers (GDGT), which are membrane lipids of bacteria and archaea, are at the base of several paleoenvironmental proxies. They are frequently applied to soils as well as lake- and marine sediments to generate records of past temperature and soil pH. To derive meaningful environmental information from these reconstructions, high analytical reproducibility is required. Based on submitted results by 39 laboratories from across the world, which employ a diverse range of analytical and quantification methods, we explored the reproducibility of brGDGT-based proxies (MBT′_5ME, IR, and #rings_tetra) measured on four soil samples and four soil lipid extracts. Correct identification and integration of 5- and 6-methyl brGDGTs is a prerequisite for the robust calculation of proxy values, but this can be challenging as indicated by the large inter-interlaboratory variation. The exclusion of statistical outliers improves the reproducibility, where the remaining uncertainty translates into a temperature offset from median proxy values of 0.3–0.9°C and a pH offset of 0.05–0.3. There is no apparent systematic impact of the extraction method and sample preparation steps on the brGDGT ratios. Although reported GDGT concentrations are generally consistent within laboratories, they vary greatly between laboratories. This large variability in brGDGT quantification may relate to variations in ionization efficiency or specific mass spectrometer settings possibly impacting the response of brGDGTs masses relative to that of the internal standard used. While ratio values of GDGT are generally comparable, quantities can currently not be compared between laboratories.

Original language	English
Article number	e2024GC011583
Journal	Geochemistry, Geophysics, Geosystems
Volume	25
Issue number	7
DOIs	https://doi.org/10.1029/2024GC011583
Publication status	Published - Jul 2024

Bibliographical note

Publisher Copyright:
© 2024 The Author(s). Geochemistry, Geophysics, Geosystems published by Wiley Periodicals LLC on behalf of American Geophysical Union.

Funding

The authors thank two reviewers, Sarah Feakins and Yunping Xu, for their constructive comments. In addition, we would like to thank Jorien Vonk (VU, The Netherlands) for providing Soil A from Canada, Frank Hagedorn (WSL, Switzerland) for Soil B from Switzerland, Sebastian Doetterl (ETH, Switzerland) for Soil C from Rwanda, and Christoph Haeggi (ETH, Switzerland) for Soil D from Brazil. Adele Blatter (ETH, Switzerland) has helped with the preparation of soil samples. This study received funding from NWO-Vidi Grant (192.074) awarded to FP and PRIMA (PR00P2_179783) and SNSF Starting Grant (TMSGI2_211319) grants from SNSF to CDJ. AS thanks the European Research Council for funding Consolidator Grant 771497 under Horizon 2020 program. SN, BD and TA thank GNS Science and Victoria University of Wellington for their ongoing support of the GNS/VUW Organic Geochemistry Laboratory, and the New Zealand Ministry of Business, Innovation and Employment (MBIE) in the framework of the Global Change Through Time research program (contract C05X1702).

Funders	Funder number
NWO‐Vidi
VUW
GNS Science and Victoria University of Wellington
GNS
Horizon 2020 Framework Programme
Schweizerischer Nationalfonds zur Förderung der Wissenschaftlichen Forschung	TMSGI2_211319
European Research Council	771497
Ministry of Business, Innovation and Employment	C05X1702
Nederlandse Organisatie voor Wetenschappelijk Onderzoek	192.074, PR00P2_179783

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 14 Life Below Water

Keywords

GDGT
interlaboratory comparison
round robin

Access to Document

10.1029/2024GC011583Licence: CC BY

Geochem Geophys Geosyst - 2024 - De Jonge - Interlaboratory Comparison of Branched GDGT Temperature and pH Proxies UsingFinal published version, 1.19 MBLicence: CC BY

Cite this

De Jonge, C., Peterse, F., Nierop, K. G. J., Blattmann, T. M., Alexandre, M., Ansanay-Alex, S., Austin, T., Babin, M., Bard, E., Bauersachs, T., Blewett, J., Boehman, B., Castañeda, I. S., Chen, J., Conti, M. L. G., Contreras, S., Cordes, J., Davtian, N., van Dongen, B., ... Zhou, A. (2024). Interlaboratory Comparison of Branched GDGT Temperature and pH Proxies Using Soils and Lipid Extracts. Geochemistry, Geophysics, Geosystems, 25(7), Article e2024GC011583. https://doi.org/10.1029/2024GC011583

@article{254a092d37f045f3bb57846c65ef9b8a,

title = "Interlaboratory Comparison of Branched GDGT Temperature and pH Proxies Using Soils and Lipid Extracts",

abstract = "Ratios of glycerol dialkyl glycerol tetraethers (GDGT), which are membrane lipids of bacteria and archaea, are at the base of several paleoenvironmental proxies. They are frequently applied to soils as well as lake- and marine sediments to generate records of past temperature and soil pH. To derive meaningful environmental information from these reconstructions, high analytical reproducibility is required. Based on submitted results by 39 laboratories from across the world, which employ a diverse range of analytical and quantification methods, we explored the reproducibility of brGDGT-based proxies (MBT′5ME, IR, and \#ringstetra) measured on four soil samples and four soil lipid extracts. Correct identification and integration of 5- and 6-methyl brGDGTs is a prerequisite for the robust calculation of proxy values, but this can be challenging as indicated by the large inter-interlaboratory variation. The exclusion of statistical outliers improves the reproducibility, where the remaining uncertainty translates into a temperature offset from median proxy values of 0.3–0.9°C and a pH offset of 0.05–0.3. There is no apparent systematic impact of the extraction method and sample preparation steps on the brGDGT ratios. Although reported GDGT concentrations are generally consistent within laboratories, they vary greatly between laboratories. This large variability in brGDGT quantification may relate to variations in ionization efficiency or specific mass spectrometer settings possibly impacting the response of brGDGTs masses relative to that of the internal standard used. While ratio values of GDGT are generally comparable, quantities can currently not be compared between laboratories.",

keywords = "GDGT, interlaboratory comparison, round robin",

author = "\{De Jonge\}, Cindy and Francien Peterse and Nierop, \{Klaas G.J.\} and Blattmann, \{Thomas M.\} and Marcelo Alexandre and Salome Ansanay-Alex and Thomas Austin and Mathieu Babin and Edouard Bard and Thorsten Bauersachs and Jerome Blewett and Brenna Boehman and Casta{\~n}eda, \{Isla S.\} and Junhui Chen and Conti, \{Martina L.G.\} and Sergio Contreras and Julia Cordes and Nina Davtian and \{van Dongen\}, Bart and Bella Duncan and Elling, \{Felix J.\} and Valier Galy and Shaopeng Gao and Jens Hefter and Hinrichs, \{Kai Uwe\} and Helling, \{Mitchell R.\} and Mariska Hoorweg and Ellen Hopmans and Juzhi Hou and Yongsong Huang and Arnaud Huguet and Guodong Jia and Cornelia Karger and Keely, \{Brendan J.\} and Stephanie Kusch and Hui Li and Jie Liang and Lipp, \{Julius S.\} and Weiguo Liu and Hongxuan Lu and Kai Mangelsdorf and Hayley Manners and \{Martinez Garcia\}, Alfredo and Guillemette Menot and Gesine Mollenhauer and Naafs, \{B. David A.\} and Sebastian Naeher and O'Connor, \{Lauren K.\} and Pearce, \{Ethan M.\} and Ann Pearson and Zhiguo Rao and Marta Rodrigo-G{\'a}miz and Chris Rosendahl and Frauke Rostek and Rui Bao and Prasanta Sanyal and Florence Schubotz and Wesley Scott and Rahul Sen and Appy Sluijs and Rienk Smittenberg and Ioana Stefanescu and Jia Sun and Paul Sutton and Jess Tierney and Eduardo Tejos and Joan Villanueva and Huanye Wang and Josef Werne and Masanobu Yamamoto and Huan Yang and Aifeng Zhou",

note = "Publisher Copyright: {\textcopyright} 2024 The Author(s). Geochemistry, Geophysics, Geosystems published by Wiley Periodicals LLC on behalf of American Geophysical Union.",

year = "2024",

month = jul,

doi = "10.1029/2024GC011583",

language = "English",

volume = "25",

journal = "Geochemistry, Geophysics, Geosystems",

issn = "1525-2027",

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De Jonge, C, Peterse, F , Nierop, KGJ, Blattmann, TM, Alexandre, M, Ansanay-Alex, S, Austin, T, Babin, M, Bard, E, Bauersachs, T, Blewett, J, Boehman, B, Castañeda, IS, Chen, J, Conti, MLG, Contreras, S, Cordes, J, Davtian, N, van Dongen, B, Duncan, B, Elling, FJ, Galy, V, Gao, S, Hefter, J, Hinrichs, KU, Helling, MR, Hoorweg, M, Hopmans, E, Hou, J, Huang, Y, Huguet, A, Jia, G, Karger, C, Keely, BJ, Kusch, S, Li, H, Liang, J, Lipp, JS, Liu, W, Lu, H, Mangelsdorf, K, Manners, H, Martinez Garcia, A, Menot, G, Mollenhauer, G, Naafs, BDA, Naeher, S, O'Connor, LK, Pearce, EM, Pearson, A, Rao, Z, Rodrigo-Gámiz, M, Rosendahl, C, Rostek, F, Bao, R, Sanyal, P, Schubotz, F, Scott, W, Sen, R, Sluijs, A, Smittenberg, R, Stefanescu, I, Sun, J, Sutton, P, Tierney, J, Tejos, E, Villanueva, J, Wang, H, Werne, J, Yamamoto, M, Yang, H & Zhou, A 2024, 'Interlaboratory Comparison of Branched GDGT Temperature and pH Proxies Using Soils and Lipid Extracts', Geochemistry, Geophysics, Geosystems, vol. 25, no. 7, e2024GC011583. https://doi.org/10.1029/2024GC011583

TY - JOUR

T1 - Interlaboratory Comparison of Branched GDGT Temperature and pH Proxies Using Soils and Lipid Extracts

AU - De Jonge, Cindy

AU - Peterse, Francien

AU - Nierop, Klaas G.J.

AU - Blattmann, Thomas M.

AU - Alexandre, Marcelo

AU - Ansanay-Alex, Salome

AU - Austin, Thomas

AU - Babin, Mathieu

AU - Bard, Edouard

AU - Bauersachs, Thorsten

AU - Blewett, Jerome

AU - Boehman, Brenna

AU - Castañeda, Isla S.

AU - Chen, Junhui

AU - Conti, Martina L.G.

AU - Contreras, Sergio

AU - Cordes, Julia

AU - Davtian, Nina

AU - van Dongen, Bart

AU - Duncan, Bella

AU - Elling, Felix J.

AU - Galy, Valier

AU - Gao, Shaopeng

AU - Hefter, Jens

AU - Hinrichs, Kai Uwe

AU - Helling, Mitchell R.

AU - Hoorweg, Mariska

AU - Hopmans, Ellen

AU - Hou, Juzhi

AU - Huang, Yongsong

AU - Huguet, Arnaud

AU - Jia, Guodong

AU - Karger, Cornelia

AU - Keely, Brendan J.

AU - Kusch, Stephanie

AU - Li, Hui

AU - Liang, Jie

AU - Lipp, Julius S.

AU - Liu, Weiguo

AU - Lu, Hongxuan

AU - Mangelsdorf, Kai

AU - Manners, Hayley

AU - Martinez Garcia, Alfredo

AU - Menot, Guillemette

AU - Mollenhauer, Gesine

AU - Naafs, B. David A.

AU - Naeher, Sebastian

AU - O'Connor, Lauren K.

AU - Pearce, Ethan M.

AU - Pearson, Ann

AU - Rao, Zhiguo

AU - Rodrigo-Gámiz, Marta

AU - Rosendahl, Chris

AU - Rostek, Frauke

AU - Bao, Rui

AU - Sanyal, Prasanta

AU - Schubotz, Florence

AU - Scott, Wesley

AU - Sen, Rahul

AU - Sluijs, Appy

AU - Smittenberg, Rienk

AU - Stefanescu, Ioana

AU - Sun, Jia

AU - Sutton, Paul

AU - Tierney, Jess

AU - Tejos, Eduardo

AU - Villanueva, Joan

AU - Wang, Huanye

AU - Werne, Josef

AU - Yamamoto, Masanobu

AU - Yang, Huan

AU - Zhou, Aifeng

PY - 2024/7

Y1 - 2024/7

N2 - Ratios of glycerol dialkyl glycerol tetraethers (GDGT), which are membrane lipids of bacteria and archaea, are at the base of several paleoenvironmental proxies. They are frequently applied to soils as well as lake- and marine sediments to generate records of past temperature and soil pH. To derive meaningful environmental information from these reconstructions, high analytical reproducibility is required. Based on submitted results by 39 laboratories from across the world, which employ a diverse range of analytical and quantification methods, we explored the reproducibility of brGDGT-based proxies (MBT′5ME, IR, and #ringstetra) measured on four soil samples and four soil lipid extracts. Correct identification and integration of 5- and 6-methyl brGDGTs is a prerequisite for the robust calculation of proxy values, but this can be challenging as indicated by the large inter-interlaboratory variation. The exclusion of statistical outliers improves the reproducibility, where the remaining uncertainty translates into a temperature offset from median proxy values of 0.3–0.9°C and a pH offset of 0.05–0.3. There is no apparent systematic impact of the extraction method and sample preparation steps on the brGDGT ratios. Although reported GDGT concentrations are generally consistent within laboratories, they vary greatly between laboratories. This large variability in brGDGT quantification may relate to variations in ionization efficiency or specific mass spectrometer settings possibly impacting the response of brGDGTs masses relative to that of the internal standard used. While ratio values of GDGT are generally comparable, quantities can currently not be compared between laboratories.

AB - Ratios of glycerol dialkyl glycerol tetraethers (GDGT), which are membrane lipids of bacteria and archaea, are at the base of several paleoenvironmental proxies. They are frequently applied to soils as well as lake- and marine sediments to generate records of past temperature and soil pH. To derive meaningful environmental information from these reconstructions, high analytical reproducibility is required. Based on submitted results by 39 laboratories from across the world, which employ a diverse range of analytical and quantification methods, we explored the reproducibility of brGDGT-based proxies (MBT′5ME, IR, and #ringstetra) measured on four soil samples and four soil lipid extracts. Correct identification and integration of 5- and 6-methyl brGDGTs is a prerequisite for the robust calculation of proxy values, but this can be challenging as indicated by the large inter-interlaboratory variation. The exclusion of statistical outliers improves the reproducibility, where the remaining uncertainty translates into a temperature offset from median proxy values of 0.3–0.9°C and a pH offset of 0.05–0.3. There is no apparent systematic impact of the extraction method and sample preparation steps on the brGDGT ratios. Although reported GDGT concentrations are generally consistent within laboratories, they vary greatly between laboratories. This large variability in brGDGT quantification may relate to variations in ionization efficiency or specific mass spectrometer settings possibly impacting the response of brGDGTs masses relative to that of the internal standard used. While ratio values of GDGT are generally comparable, quantities can currently not be compared between laboratories.

KW - GDGT

KW - interlaboratory comparison

KW - round robin

UR - https://www.scopus.com/pages/publications/85199069444

U2 - 10.1029/2024GC011583

DO - 10.1029/2024GC011583

M3 - Article

AN - SCOPUS:85199069444

SN - 1525-2027

VL - 25

JO - Geochemistry, Geophysics, Geosystems

JF - Geochemistry, Geophysics, Geosystems

IS - 7

M1 - e2024GC011583

ER -

Interlaboratory Comparison of Branched GDGT Temperature and pH Proxies Using Soils and Lipid Extracts

Abstract

Bibliographical note

Funding

UN SDGs

Keywords

Access to Document

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